DE2916299A1 - Laminated metallic material contg. fibre reinforcing layers - where refractory fibre fabrics are embedded in core of brazed laminate - Google Patents

Abstract

One or more layers of a fibre fabric are stacked alternately with one or more layers of a metal with low m. pt., esp. an Al alloy. Both sides of the stack are then covered by an outer layer of a metal with better mechanical and thermal properties than metal. The stack is next brazed under pressure, so metal diffuses into fabric. Fabric pref. consists of parallel fibres of SiC, Al2O3, B or C, joined together by fine transverse strips. Layers are pref. foils or thin sheets of Al, steel, Ni, or Ti. When more than one layer is used, the fibres in one layer are pref. aligned at 90 degrees w.r.t. the fibres in the next layer. This laminate is simpler to mfr., and withstands higher temps., than the material described in US 4029838.

Description

Method for producing a composite material

The invention is based on a method as described in the preamble of the claims 1 specified type. A composite material built according to this process is already known from U.S. Patent 4,029,838. In the case of the composite material described therein outer layers are made of aluminum reinforced with boron fibers, inner layers Made of synthetic resin reinforced with carbon fibers with outer layers of titanium foils connected to one another by adhesive layers. The layers are connected thereby in several procedural steps of different duration with different Temperatures and pressures, the highest temperature corresponding to the one used Resin matrix and the adhesive is around 1770C. The high resistance this composite material against impact, breakage and erosion is thus by an extremely Complicated manufacturing process bought.

In addition, this material can only be used for parts that have to withstand relatively low temperature loads.

The object of the invention is to provide a method as described in the preamble of claim 1 specified type to improve that the composite material to be created is easy to manufacture and can also be exposed to higher temperatures.

The solution to this task is carried out by the in the characterizing part of claim 1 specified method steps, wherein in the dependent claims 2 to 4 still advantageous and beneficial developments are claimed, some of which Have overlaps with the state of the art.

The method according to the invention can be used in a simple and inexpensive manner Kind of a metallic composite material protected by cover layers depending on the used Fibers and the layers of the low melting point Metal can be adjusted in its strength properties. With the preferred Using aluminum as a matrix metal will have a low specific weight achieved, so that the composite material is used in particular for purposes of lightweight construction Can be found. In addition, by choosing the number of layers of fiber fabric and the low-melting-point diffusing metal ends to achieve any desired layer thickness will. The outer layers essentially have the task of the composite material To give a high-strength outer skin that can withstand extremely high external loads like rain, erosion, cavitation and foreign body impacts. Using of cover layers made of e.g. high-strength steel or titanium is thus the one according to the invention Composite even for parts exposed to the flow of supersonic parts Suitable for aircraft. The brazing of the layer package can be carried out according to known methods, e.g. with a vacuum bag in an autoclave.

The features of the invention and its technical advantages emerge also from the following description of exemplary embodiments with reference to the drawing. It shows in sectional views Fig. 1 the simplest case of each other layering layers for the production of the composite material: One layer of the fiber fabric each and the low melting point metal prior to brazing; Fig. 2 corresponds to several layers. Fig. 1 before brazing; 3 shows a finished composite material from the layers of Fig. 2 after brazing.

In Figures 1 to 3 are because of a clear graphic Representation of the individual layers and layers compared to the actual design much more strongly drawn.

In Fig. 1 is in preparation for brazing between two cover layers 2 each a layer of low-melting metal 3 and fiber fabric 4 arranged. as Cover layers 2 can be foils or thin sheets, depending on the load and use made of e.g. aluminum, steel, nickel, titanium or other solid materials will. An aluminum alloy should preferably be used as the low-melting metal be, z * Bo Alst 12.

However, other low-melting metals and their alloys can also be used come into use. The fiber fabric 4 consists of unidirectional parallel lying fibers 5 made of e.g. silicon carbide, aluminum oxide, boron or carbon, which are held by fine woven ribbons 6 woven across them. The woven ribbons 6 can be made from harder aluminum than layer 3 or from other materials exist, they serve to fix the fibers 5 both during transport and during Brazing and the associated pressing of the layers.

In Fig. 2 are three layers of low-melting metal 3 and Fiber fabric 4 arranged between cover layers 2. The corresponding to FIGS. 1 and 2 prepared layered layers 2 to 4 are placed under pressure, e.g. in an autoclave, at the appropriate temperature for the individual materials used subjected to a brazing process. The layers 3 diffuse from the low-melting point Material into the fiber fabric 4 and form a coherent one according to FIG. 3 Layer 8 made of fiber-reinforced metal, in turn with the cover layers 2 connects to the desired metal composite material. The individual layers Fiber fabric 4 can be arranged both in parallel and in a crisscross manner to each other are inserted between the cover layers Blank page

Claims (4)

Method for producing a composite material Claims Process for producing a composite material from one or more fiber-reinforced materials Layers that are covered by clean metal layers are g e k e n n -z e i c hn e t through the following process steps a) one or more layers of one Fiber fabric (4) are alternated with one or more layers of a low melting point Metal (3), in particular a low-melting aluminum alloy, layered, b) cover layers (2) made of a metal are placed on both sides of the layered layers applied, which opposite the low-melting metal (3) has better mechanical and thermal properties, c) the outer layers (2) with the layers sandwiched between them are under the action of pressure brazed, the low-melting metal (3) diffusing into the fiber fabric (4). 2. The method according to claim 1, i.e. g e k e n n z e i c h -n e t that for the production of the fiber fabric (4) parallel fibers (5) made of silicon carbide, Aluminum oxide, boron or carbon with transversely directed fine woven ribbons (6) with one another get connected. 3. The method according to claims 1 and 2, characterized g e k e n n -z e i c h n e t that for the cover layers (2) foils or thin sheets of aluminum, Steel, nickel or titanium can be used. 4. The method according to claims 1 and 2, characterized g e k e n n -z e i c h n e t that the individual layers of the fiber fabric (4) in an intersecting direction be arranged to each other.